Transistor structures and methods for making the same

ABSTRACT

Enhancement mode, field effect transistors wherein at least a portion of the transistor structure may be substantially transparent. One variant of the transistor includes a channel layer comprising a substantially insulating, substantially transparent, material selected from ZnO or SnO 2 . A gate insulator layer comprising a substantially transparent material is located adjacent to the channel layer so as to define a channel layer/gate insulator layer interface. A second variant of the transistor includes a channel layer comprising a substantially transparent material selected from substantially insulating ZnO or SnO 2 , the substantially insulating ZnO or SnO 2  being produced by annealing. Devices that include the transistors and methods for making the transistors are also disclosed.

PRIORITY CLAIM

This is a divisional of U.S. patent application Ser. No. 10/307,162, filed Nov. 27, 2002, which claims the benefit of U.S. Provisional Application 60/382,696, filed May 21, 2002, both of which are incorporated herein by reference.

FIELD

The present disclosure relates to transistor structures such as, for example, transparent transistors.

BACKGROUND

The microelectronics industry and research community is undertaking efforts to fabricate electronic devices (e.g., diodes and transistors) that are transparent to the portion of the electromagnetic spectrum that is visible to the human eye. Circuits made of such devices would offer unique opportunities for innovation or improvement of consumer-, automotive-, and military-electronics systems.

For example, active-matrix liquid crystal displays (AMLCD) are employed extensively in laptop computers and other information display products. The operation of an AMLCD display requires that each picture or display element (pixel) have a corresponding thin-film transistor (TFT) associated with it for selecting or addressing the pixel to be on or off. Currently, AMLCD displays employ transistor materials that may be deposited onto glass substrates but are not transparent (usually amorphous, polycrystalline, or continuous-grain silicon are the materials used to fabricate TFTs on glass). Thus, the portion of the display glass occupied by the addressing electronics is not available for transmission of light through the display. Therefore, the availability of transparent transistors for AMLCD addressing would improve display performance by allowing more light to be transmitted through the display.

BRIEF DESCRIPTION OF THE DRAWINGS

Certain embodiments will be described in more detail with reference to the following drawings:

FIG. 1 is a sectional view of a first embodiment of a presently disclosed transistor structure;

FIG. 2 is a sectional view of a second embodiment of a presently disclosed transistor structure;

FIG. 3 is a sectional view of a third embodiment of a presently disclosed transistor structure;

FIG. 4 is a graph showing drain-source current (I_(DS)) versus drain-source voltage (V_(DS)), as a function of gate-source voltage (V_(GS)), for the transistor structure depicted in FIG. 1 (the gate-source voltage varies from +40V (top curve) to +2 V in 2 V steps);

FIG. 5 is a graph showing the I_(DS) vs. V_(GS) characteristics for the transistor structure depicted in FIG. 1 at three different drain-source voltages;

FIG. 6 is a graph showing inverter transfer characteristics for the transistor structure depicted in FIG. 1 using a transparent thin-film resistor load (R=70 MΩ) and a power supply voltage, V_(DD)=40 V; and

FIG. 7 is a graph showing the optical transmission characteristics through the source or drain portion of the transistor structure depicted in FIG. 1.

DETAILED DESCRIPTION OF SEVERAL EMBODIMENTS

For ease of understanding, the following terms used herein are described below in more detail:

“Enhancement-mode transistor” means a transistor in which there is negligible current flow (i.e., there is no conducting channel) between a source and a drain at zero gate voltage. In other words, the transistor device is “normally off.” In contrast, a depletion-mode transistor is “normally on” meaning that a current flows between a source and a drain at zero gate voltage.

“Gate” generally refers to the insulated gate terminal of a three terminal FET when used in the context of a transistor circuit configuration.

“Substantially insulating” can include insulating materials (e.g., materials having a resistivity of greater than about 10¹⁰ Ω-cm) and semi-insulating materials (e.g., materials having a resistivity of about 10³ Ω-cm to about 10¹⁰ Ω-cm).

“Substantially transparent” generally denotes a material or construct that does not absorb a substantial amount of light in the visible portion (and/or infrared portion in certain variants) of the electromagnetic spectrum.

“Vertical” means substantially perpendicular to the surface of a substrate.

The preceding term descriptions are provided solely to aid the reader, and should not be construed to have a scope less than that understood by a person of ordinary skill in the art or as limiting the scope of the appended claims.

Disclosed herein are enhancement mode, field effect transistors wherein at least a portion of the transistor structure may be substantially transparent. Devices that include the transistors and methods for making the transistors are also disclosed.

One variant of the transistor includes a channel layer comprising a substantially insulating, substantially transparent, material selected from ZnO or SnO₂. A gate insulator layer comprising a substantially transparent material is located adjacent to the channel layer so as to define a channel layer/gate insulator layer interface. The transistor also includes a source that can inject electrons into the channel layer for accumulation at the channel layer/gate insulator layer interface and a drain that can extract electrons from the channel layer.

A second variant of the transistor includes a channel layer comprising a substantially transparent material selected from substantially insulating ZnO or substantially insulating SnO₂, the substantially insulating ZnO or substantially insulating SnO₂ being produced by annealing. A gate insulator layer is located adjacent to the channel layer and comprises a substantially transparent material. The transistor also includes a source, a drain, and a gate electrode.

A method for making the transistors includes providing a gate insulating layer, depositing ZnO or SnO₂ onto at least a portion of a surface of the gate insulating layer, and annealing the ZnO or SnO₂ for about 1 to about 5 minutes at a temperature of about 300 to about 1000° C. in an oxidative atmosphere.

The transistors may be included in optoelectronic display devices as switches coupled to at least one display element. Another disclosed device is a substantially transparent, dynamic random-access memory cell, comprising a substantially transparent capacitor coupled to the transistor. A further application of the transistors is in substantially transparent inverters wherein the transistor is coupled to a load device.

In general, the transistor structure includes a substrate, a gate electrode, a gate insulator layer, a channel layer, a source and a drain. The channel layer may be positioned adjacent to the gate insulator layer so that a surface of the channel layer is contiguous with a surface of the gate insulator layer. The contact region of the channel layer surface and the gate insulator layer surface is referred to herein as the channel layer/gate insulator layer interface. In exemplary constructs, the channel layer insulating material is different than the gate insulator layer material and the channel layer/gate insulator layer interface defines a discrete material boundary.

A feature of an embodiment of the transistor structure is that the channel layer/gate insulator layer interface may define a conducting channel for the flow of electrons from the source to the drain. In other words, the transistor may be classified as a “surface-channel” or “interface-channel” device. The applied gate voltage facilitates electron accumulation in the channel layer/gate insulator layer interface region. In addition, the applied voltage enhances electron injection from the source to the channel layer/gate insulator layer interface and electron extraction therefrom by the drain.

Another characteristic of the transistor structure is that selected embodiments of the construct or combination of the channel layer and the gate insulator layer may exhibit an optical transmission of at least about 90%, more particularly at least about 95%, across the visible portion (and/or infrared portion in certain variants) of the electromagnetic spectrum. Each of the additional components of the structure (i.e., substrate, gate electrode, source/drain terminals) may be optionally opaque or substantially transparent depending upon the desired end use of the transistor. In certain embodiments, the transistor structure as a whole (and/or individual components of the transistor) may exhibit an optical transmission of at least about 50%, more particularly at least about 70%, and most particularly at least about 90%, across the visible portion (and/or infrared portion in certain variants) of the electromagnetic spectrum.

A further feature of the FET disclosed herein is that it may easily be fabricated as a thin film transistor (TFT). For example, relatively low processing temperatures (e.g., not exceeding about 800° C.) may be used and there is no need for ion implanting to set the channel threshold voltage and define the source and drain contacts in certain variants of the FET structure. Such TFTs typically are very useful in association with optoelectronic device as explained below in more detail.

The channel layer typically is made from a substantially insulating material that is also substantially transparent. A negligible amount of electrons is inherently available in the bulk portion of the channel layer since the channel layer is made from a substantially insulating material. In addition, the substantially insulating channel layer may provide inherent electrical isolation for multiple devices sharing a continuous channel layer film (with patterned gate, source, and drain electrodes defining each device). Such inherent device isolation means that patterning of the channel layer film is not necessary since conductivity at the channel layer/gate insulator layer is exhibited only beneath the patterned gate electrodes.

Illustrative materials for the channel layer include ZnO and SnO₂. Insulating ZnO and SnO₂ may be made by an annealing process, particularly rapid thermal annealing (RTA). Such insulating ZnO and SnO₂ typically exhibit a bandgap of less than about 5 eV.

For example, a layer of ZnO may be deposited (e.g., by sputtering or chemical vapor deposition) and subsequently undergo annealing for about 1 to about 5 minutes at a temperature of about 300 to about 1000° C., particularly about 700 to about 800° C., in a substantially oxidative atmosphere. Although not bound by any theory, it is believed that such a process should result in the incorporation of more oxygen into the ZnO layer, thus reducing the oxygen vacancy concentration. Oxygen vacancies in ZnO can render it n-type and conductive. High temperature (i.e., at least about 700° C.) annealing in inert atmospheres such as argon may also produce insulating ZnO. Although not bound by any theory, such higher temperature anneals may improve the ZnO crystallinity, thus improving the electron transport properties. Such insulating ZnO typically is not doped.

Similarly, a layer of SnO₂ may be deposited (e.g., by sputtering or chemical vapor deposition) and subsequently undergo annealing for about 1 to about 5 minutes at a temperature of about 300 to about 1000° C., particularly about 700 to about 900° C., in a substantially oxidative atmosphere. Although not bound by any theory, it is believed that such a process should result in the incorporation of more oxygen into the SnO₂ layer, thus reducing the oxygen vacancy concentration. Oxygen vacancies in SnO₂ can render it n-type and conductive. High temperature (i.e., greater than about 700° C.) annealing in inert atmospheres such as argon may also produce insulating SnO₂. Although not bound by any theory, such higher temperature anneals may improve the SnO₂ crystallinity, thus improving the electron transport properties. The resistivity of the SnO₂ may also be enhanced by substitutional doping with an acceptor dopant such as, for example, Al, In, Ga, Bi, B, La, Sc, Y, Lu, Er, Ho, and mixtures thereof.

The thickness of the channel layer may vary, and according to particular examples it can range from about 10 to about 500 nm. The channel length also may vary, and according to particular examples it can range from about 1,000 to about 100,000 nm.

The gate insulator layer may be made from any material exhibiting insulating properties required for gate insulators, particularly a substantially transparent material. Gate insulator materials typically exhibit a bandgap of greater than about 5 eV. Illustrative materials include substantially transparent materials such as aluminum-titanium oxide (Al₂O₃/TiO₂), Al₂O₃, MgO, SiO₂, silicon nitride, and silicon oxynitride. One distinctive example of a substantially transparent material is aluminum-titanium oxide grown by atomic layer deposition. The thickness of the gate insulator layer may vary, and according to particular examples it can range from about 10 to about 300 nm. The gate insulator layer may be introduced into the structure by techniques such as chemical vapor deposition, sputtering, atomic layer deposition, or evaporation.

Source/drain terminals refer to the terminals of a FET, between which conduction occurs under the influence of an electric field. Designers often designate a particular source/drain terminal to be a “source” or a “drain” on the basis of the voltage to be applied to that terminal when the FET is operated in a circuit. The source and drain may be made from any suitable conductive material such as an n-type material. The source and drain materials are optionally opaque materials or substantially transparent materials. Illustrative materials include transparent, n-type conductors such as indium-tin oxide (ITO), ZnO, SnO₂, or In₂O₃ or opaque metals such as Al, Cu, Au, Pt, W, Ni, or Ti. Especially useful materials for the source and drain are those that can inject (and extract) electrons into the channel layer insulating material. Examples of such electron injection materials include indium-tin oxide, LaB₆, and ZnO:Al.

The source and drain may be introduced into the structure by techniques such as chemical vapor deposition, sputtering, evaporation, and/or doping of the channel layer material via diffusion or ion implantation. The source and drain terminals may be fabricated such that they are geometrically symmetrical or non-symmetrical.

The gate electrode may be made from any suitable conductive material. The gate electrode material is optionally an opaque material or a substantially transparent material. Illustrative gate electrode materials include transparent, n-type conductors such as indium-tin oxide (ITO), ZnO, SnO₂, or In₂O₃, or opaque metals such as Al, Cu, Au, Pt, W, Ni, or Ti. The thickness of the gate electrode may vary, and according to particular examples it can range from about 50 to about 1000 nm. The gate electrode may be introduced into the structure by chemical vapor deposition, sputtering, evaporation and/or doping.

“Substrate”, as used herein, refers to the physical object that is the basic workpiece that is transformed by various process operations into the desired microelectronic configuration. A substrate may also be referred to as a wafer. Wafers may be made of semiconducting, non-semiconducting, or combinations of semiconducting and non-semiconducting materials. The substrate may be made from any suitable material. The substrate material is optionally an opaque material or a substantially transparent material. Illustrative substrate materials include glass and silicon. The thickness of the substrate may vary, and according to particular examples it can range from about 100 μm to about 1 cm.

Electrical contact to the gate electrode, source, drain and substrate may be provided in any manner. For example, metal lines, traces, wires, interconnects, conductors, signal paths and signaling mediums may be used for providing the desired electrical connections. The related terms listed above, are generally interchangeable, and appear in order from specific to general. Metal lines, generally aluminum (Al), copper (Cu) or an alloy of Al and Cu, are conductors that provide signal paths for coupling or interconnecting, electrical circuitry. Conductors other than metal may also be utilized.

An illustrative n-channel operation of the transistor involves applying a positive voltage to the gate electrode, grounding the source, and applying a positive voltage to the drain. For example, a voltage of about 5 to about 40 V may be applied to the gate electrode and the drain during operation. The threshold voltage may range from about 1 to about 20 V. Electrons flow from the source, along the conducting channel created at the channel layer/gate insulator layer interface, and out of the transistor through the drain. The effective mobility of the electrons at the interface may vary depending upon the specific structure, but could range, for example, from about 0.05 to about 20 cm²V⁻¹s⁻¹. Simply removing the positive voltage applied to the gate electrode turns the transistor off since the transistor is an enhancement-mode transistor.

The transistor structures disclosed herein may be used for fabricating chips, integrated circuits, monolithic devices, semiconductor devices, and microelectronic devices. One example of a microelectronic device is an optoelectronic device. An illustrative optoelectronic device is an active-matrix liquid-crystal display (AMLCD).

One exemplar device is an optoelectronic display device that includes elements having electrodes and an electro-optical material disposed between the electrodes. A connection electrode of the transparent transistor may be connected to an electrode of the display element, while the switching element and the display element overlap one another at least partly. An optoelectronic display element is here understood to be a display element whose optical properties change under the influence of an electrical quantity such as current or voltage such as, for example, an element usually referred to as liquid crystal display (LCD). The presently detailed transparent transistor is sufficiently fast for switching the display element at such a high frequency that the use of the transparent transistor as a switching element in a liquid crystal display is possible. The display element acts in electrical terms as a capacitor that is charged or discharged by the accompanying transparent transistor. The optoelectronic display device may include many display elements each with its own transparent transistor, for example, arranged in a matrix. The transparent transistors may be arrayed for LCD devices as described, for example, in Kim, “Thin-Film-Transistor Device Design”, Information Display 2/02, p. 26 (2002).

Other examples of microelectronic devices that could employ the transistor structure shown herein include inverters, analog amplifiers and single-transistor dynamic random-access memory (DRAM) cells, and like devices.

For instance, a transparent enhancement-mode transistor whose source is connected to one terminal of a transparent capacitor, while the other terminal of the capacitor is grounded, constitutes a transparent single-transistor dynamic random-access memory (DRAM) cell. In such a DRAM cell, information is stored as charge on a capacitor, with the enhancement-mode transistor serving as an access transistor that controls the capacitor charge state. Usually in such a DRAM cell, a logic 0 is represented by negligible capacitor charge and a concomitantly small capacitor voltage. In contrast, a logic 1 is obtained by charging the capacitor, thus increasing the capacitor voltage until it approaches the power supply voltage.

The entire DRAM cell described herein, or a portion thereof, is transparent. Fabricating transparent capacitors and connecting them to a transparent transistor to realize a DRAM cell can be accomplished using various techniques. Specifically, a transparent capacitor may be constructed by sandwiching a transparent insulator layer, using materials such as Al₂O3 or SiO₂, between two transparent conductors, using materials such as indium-tin oxide, ZnO, or SnO₂.

Illustrative examples of specific transistor structures are shown in FIGS. 1-3. The specific examples described below are for illustrative purposes and should not be considered as limiting the scope of the appended claims. In FIGS. 1-3 like reference numerals refer to like elements unless otherwise indicated.

FIG. 1

A TFT structure 1 is illustrated that was fabricated on a one-inch by one-inch thick composite substrate. The platform includes a glass substrate 2, a 200 nm thick, indium-tin oxide (ITO) gate electrode 3 coated on the substrate 2, and a 200 nm thick, aluminum-titanium oxide gate insulator layer 4.

A ZnO channel and an ITO source/drain electrode film was deposited via ion beam sputtering in 10⁻⁴ Torr of Ar/O₂ (80%/20%); the substrate was unheated during deposition. The ZnO channel layer 5 (100 nm thick), an ITO source electrode 6 (300 nm thick) and, an ITO drain electrode 7 (300 nm thick) were defined using a shadow mask. The resulting structure defines a channel layer/gate insulator layer interface 8. A 300° C. rapid thermal anneal (RTA) in Ar immediately prior to both the ZnO and ITO depositions served to remove adsorbed contaminants from the exposed surface, yielding a noticeable improvement in film quality (particularly for ITO films). After deposition of the ZnO layer, a RTA (typically in O₂ or Ar, at 600 to 800° C.) was employed to increase the ZnO channel resistivity and to improve the electrical quality of the channel layer/gate insulating layer interface 8. Following deposition of the ITO source/drain electrodes, a 300° C. RTA in O₂ was used to improve the transparency of the ITO layer. In the transistor structure 1 the source/drain electrodes 6 and 7 are disposed on the top surface of the channel layer 5 (from a vertical perspective) and the gate electrode 3 and channel layer 5 are disposed, respectively, on opposing surfaces of the gate insulator layer 4. Consequently, structure 1 allows for high temperature processing of the ZnO channel layer 5 prior to deposition and processing of the ITO source/drain electrodes 6 and 7. Certain electrical and physical characteristics of the TFT structure 1 were evaluated as described below and illustrated in FIGS. 4-7.

With reference to FIG. 4, n-channel, enhancement-mode behavior is obtained as demonstrated by the fact that a positive gate voltage in excess of ˜15 V (the threshold) is required to obtain appreciable drain-source current. These I_(DS)-V_(DS) curves exhibit prototypical FET characteristics; of particular significance is the flatness of these curves at large drain voltages (i.e. they exhibit ‘hard’ saturation). The drain and gate voltages employed are rather large compared to conventional FETs; gate and drain voltages can be reduced to the range expected for typical FET operation (i.e. ˜5-10 V), by simply reducing the gate insulator thickness. In the TFT structure 1 the insulator thickness is ˜200 nm, as optimized for electroluminescent display applications; if an otherwise identical insulator is rescaled to a thickness of 20 nm, the gate and drain voltages will be reduced by a factor of approximately 10.

The I_(DS) of structure 1 is currently rather small (i.e., I_(DS) (max) is about 6 μA in FIG. 4). A larger I_(DS) may be desirable for most applications. The magnitude of I_(DS) is determined by two factors. One is the effective mobility of the channel electrons, μ_(eff) (about 0.05-0.2 cm²V⁻¹s⁻¹ for the TFT structure 1). Process/device optimization should result in an improvement in μ_(eff) by a factor of about 2 to 100 which will lead to a corresponding increase in I_(DS). The second factor is the aspect ratio. The aspect ratio of the TFT structure 1 (the physical width of the gate, Z, divided by the length of the gate, L) is about 2 (with Z=2L=6000 μm). A larger aspect ratio will lead to a larger I_(DS).

FIG. 5 illustrates the I_(DS)-V_(GS) characteristics of the TFT structure 1 at three different drain voltages. This figure shows that there is a factor of 10⁵-10⁶ difference between the ‘on’ and ‘off’ currents when the transistor is used as a switch.

FIG. 6 shows the transfer characteristics of the TFT structure 1 when it is employed as an inverter. A ZnO transparent thin-film resistor (R=70 MΩ) is used as the inverter passive load with a power supply voltage V_(DD)=40 V. A logic swing of about 15 V between 15 and 30 V is clearly evident from this curve. This constitutes a demonstration of the use of the presently described transparent TFT as a transparent inverter. In its simplest implementation, a logic inverter is comprised of two constituents: a transistor coupled to a load device. The load device may be a resistor, as employed in this example. Alternatively, a depletion- or enhancement-mode transistor may also be used as load devices, typically offering superior performance. The fundamental property of a logic inverter is that it performs a logical not operation, in which a logic 0 (1) input produces a logic 1 (0) output. Successful achievement of a transparent logic inverter, as described herein, is significant since the inverter is the most basic building block for achieving transparent digital electronics. Optimization of the transparent thin film transistor via reducing the insulator thickness, reducing physical dimensions, and increasing the current drive capability (increased aspect ratio and effective mobility) will lead to a significant reduction in the required power supply voltage for inverter operation.

Transparent transistors may also be employed in amplifier applications. For example, the inverter structures described above can also function as simple analog inverting amplifiers. With the appropriate DC bias at the input, a small input signal (superimposed upon the DC bias) is amplified by the inverter transfer characteristic. In addition to such simple amplifier configurations, these transistors could be directly applied in arbitrary amplifier configurations, with the limitation that the maximum operating frequency will be relatively low due to the low mobility of these devices.

FIG. 7 shows the optical transmission of the TFT structure 1 through the source 6 or drain 7 (optical transmission through the channel, not shown here, is higher than through the source or drain). The average transmission in the visible portion of the electromagnetic spectrum (450-700 nm) is about 90% (about 95% through the channel). Visually, the transparent TFT structure is essentially invisible; a slight tinting of the glass substrate is apparent upon close inspection.

FIG. 2

In another transparent TFT structure 10 version shown in FIG. 2, a source electrode 11 (100 nm thick) and a drain electrode 12 (100 nm thick) were made by selectively doping the ends of a ZnO channel layer 13 (100 nm thick) with In (or any other suitable n-type dopant). This was accomplished by ion beam sputter depositing a thin (about 5 nm) ITO layer using the source/drain shadow mask before depositing the ZnO channel film. A subsequent high-temperature (˜600-800° C.) annealing step was performed to diffusion-dope the ZnO, thus forming n-type doped source/drain regions 11 and 12. The diffusion-doping RTA may also function as the oxidizing RTA for the ZnO. ITO contacts may be placed over the source and drain regions to provide better electrical contact. The substrate 2, gate electrode 3, gate insulator layer 4, and channel layer/gate insulator layer interface 8 are the same as in FIG. 1.

FIG. 3

In a third variation of a TFT structure 20, an ITO source electrode 21 (300 nm thick) and ITO drain electrode 22 (300 nm thick) are deposited prior to formation of a ZnO channel layer 23 (100 nm thick). The ZnO channel layer 23 is subsequently deposited conformally over the ITO source/drain electrodes 21 and 22. After deposition of the ZnO, a 700° C. Ar anneal was performed, followed by a 300° C. oxygen anneal. The substrate 2, gate electrode 3, gate insulator layer 4, and channel layer/gate insulator layer interface 8 are the same as in FIG. 1.

Having illustrated and described the principles of the disclosed devices and methods with reference to several embodiments, it should be apparent that these devices and methods may be modified in arrangement and detail without departing from such principles. 

1. A method for making an enhancement mode, field effect transistor comprising: depositing ZnO or SnO₂ onto at least a portion of a surface of a gate insulating layer; and annealing the ZnO or SnO₂ for about 1 to about 5 minutes at a temperature of about 300 to about 1000° C. in an oxidative or inert atmosphere.
 2. The method according to claim 1, wherein ZnO is deposited.
 3. The method according to claim 1, wherein SnO₂ is deposited and the method further comprises introducing an acceptor dopant into the SnO₂.
 4. The method according to claim 1, wherein the gate insulator layer comprises a substantially transparent material.
 5. The method according to claim 1, wherein the annealing temperature is about 700 to about 800° C.
 6. The method according to claim 1, further comprising depositing on the ZnO or SnO₂ layer at least one material for forming a source and a drain.
 7. The method according to claim 1, further comprising depositing on the gate insulating layer at least one material for forming a source and a drain prior to depositing the ZnO or SnO₂.
 8. The method according to claim 7, wherein the material for forming a source and a drain is ion beam sputtered deposited onto the gate insulating layer, and the annealing of the ZnO diffusion dopes the ZnO with the source and drain material.
 9. The method according to claim 6, further comprising annealing the source and drain material.
 10. A method for making an enhancement mode, field effect transistor comprising: depositing ZnO or SnO₂ onto at least a portion of a surface of a gate insulating layer; and treating the ZnO or SnO₂ such that the treated ZnO or SnO₂ has a higher resistivity and a lower oxygen vacancy concentration relative to the untreated ZnO or SnO₂.
 11. The method according to claim 2, wherein the ZnO is vapor deposited.
 12. The method according to claim 10, wherein ZnO is vapor deposited.
 13. The method according to claim 11, wherein the ZnO is chemical vapor deposited or sputtered.
 14. The method according to claim 12, wherein the ZnO is chemical vapor deposited or sputtered.
 15. The method according to claim 1, wherein the field effect transistor exhibits an optical transmission through the field effect transistor of at least about 70% in the visible portion of the electromagnetic spectrum.
 16. The method according to claim 1, wherein the ZnO is not doped.
 17. The method according to claim 3, wherein the SnO₂ is vapor deposited.
 18. The method according to claim 1, wherein the ZnO or SnO₂ is annealed in an oxidative atmosphere.
 19. The method according to claim 1, wherein the ZnO or SnO₂ is annealed in an inert atmosphere.
 20. The method according to claim 1, wherein the deposited and annealed ZnO or SnO₂ forms a substantially insulating, substantially transparent, material. 